NO841699L - CONTROL FOR LIGHT BEAMS - Google Patents

Description

The invention relates to a circuit for controlling the brightness of a fluorescent tube or several fluorescent tubes as stated in the preamble to claim 1.

Such circuits for controlling fluorescent tubes according to the principle of partial phase control using an attenuator are generally known and are e.g. described in the BBC technical book "Vorschaltge-råte und Schaltungen ftir Niederspannungsentladungslampen", Vorlag Girardet, Essen 5, edition 1974. All components necessary for such circuits are also described there, also special ballasts and special heating transformers that can be used instead of standard components .

The known circuit devices are very well suited for controlling the long-standing, used fluorescent tubes with a diameter of 38 mm. In recent times, however, fluorescent tubes with a diameter of 26 mm have also become common. Fluorescent tubes with a diameter of 26 mm, however, are not immediately possible to be able to control with regard to their brightness using the known circuit devices, as compared to fluorescent tubes with a diameter of 38 mm they have a higher ignition voltage which is not reliably provided with the known circuit devices.

The purpose of the invention is to provide a circuit arrangement for brightness control of fluorescent tubes with increased ignition voltage where it should be possible to use the standard components that are currently common.

According to the invention, the task is solved as indicated in the characteristic of claim 1 and where further embodiments are indicated in the subclaims.

The invention advantageously enables the continued use of the existing standard components for brightness control when changing from a lamp with a 38 mm diameter to a lamp with an increased ignition voltage. Only an additional ignition device must be provided.

The invention will now be described in more detail with reference to the accompanying drawing with the help of an exemplary embodiment.

The drawing shows a circuit for brightness control of light tubes. This circuit is based on a conventional arrangement of fluorescent tubes with a ballast device 2, a heating transformer 4 for preheating the electrode 9 of the fluorescent tube 7, an attenuator 1 and a base load device 3. The mains voltage with the phase L and the neutral conductor N is led to the input of the attenuator 1 The controlled output S of the attenuator 1 is connected via a ballast device 2 to one of the electrodes 9 of the light tube 7 and also to the S connection to the base load device 3. The output LI of the attenuator 1, which in the attenuator 1 is connected to the phase L via a switch, is connected to a first connection of the primary winding of the heating transformer 4 and to the Ll connection of the base load device 3. The neutral conductor N is connected to the N connection of the base load device 3 and to a second connection of the primary winding of the heating transformer 4 and to the electrode 9 of the fluorescent tube 7, which is not connected to the ballast device 2. The secondary winding of the heating transformer 4 is connected to the respective electrical electrodes 9.

The basic load device 3 contains an inductive load, which is connected to the connection N and S, as well as a radio noise attenuation capacitor between the Li and N connection. Instead of the basic load device 3, an incandescent lamp load (e.g. 25W) can also be connected between the outputs LI and N of the damper 1 whereby the use of fluorescent lamps 7 with a diameter of 26 mm gives better control properties than when using a basic load device 3.

Also the known fire aid in the form of a fire strip or a screen grid 5 can be used to advantage with the fluorescent tube 7 with a diameter of 26 mm to improve the control properties. Such screen grids 5 are connected via a protective resistor 8 to earth PE or to the neutral conductor N.

As the "known" circuit arrangement described until now did not provide the necessary ignition voltage, according to the invention, an additional ignition device 6 is necessary. The ignition device 6 delivers synchronous ignition pulses, which are supplied to the electrode 9, to increase the phase partial voltage at the output S of the damper 1 to the light tube 7.

The ignition device 6 contains a series connection of a phase-part calculator 61, a switch-on delay 62, a noise pulse key 63, a pulse amplifier 64, an ignition pulse generator 65 and an ignition pulse transformer 66. In addition, a mains device 67 for feeding the previously mentioned components to present.

The input to the phase partial evaluator 61 is connected to the controlled output S of the attenuator 1. In the phase partial evaluator 61, a square signal (e.g. 12V) is produced with the zener diode, whose rising edge proceeds synchronously in relation to the phase part of the positive half-wave at the input. The time element emits this square signal only approximately 4 ms after the zero crossing for the mains voltage. The square signal thus appears at the output of the phase partial evaluator 61 synchronously in relation to the rise of the divided voltage with withdrawal of the sub-range below 4 ms, the voltage rise only 4 ms after the zero crossing triggering a square signal.

The square signal generated from the phase estimator 61 finally passes through the switch-on delay 62. There, the square signal is blocked within the first 2s after switching on the attenuator 1. This delay time resulted in more of the preheating time which is appropriate for switching on the electrode 9 and for protecting them.

During the subsequent noise pulse keying 63, the square signal below a certain length (e.g. 200 p.s) is considered a noise pulse and is suppressed.

The square signal at the output of the noise pulse keying 63 is then amplified in the pulse amplifier 64 in a transistor circuit and supplied via a transfer thyristor in the ignition pulse generator 65.

The ignition pulse generator 65 is supplied with mains voltage and contains two thyristors and two capacitors, which are charged at +300V or -300V. Controlled via the square signal from the pulse amplifier 64, the thyristor discharges the capacitors across the primary winding of the ignition pulse transformer 66. On the secondary side of the ignition pulse transformer 66, the ignition pulse of 1.5kV occurs, which is supplied via a capacitor 68 to the electrode 9 of the light tube 7. The duration of the ignition pulse is sized so that a flicker-free operation of the fluorescent tube 7.

Claims (2)

1. Circuit for brightness control of a fluorescent tube or several fluorescent tubes," the fluorescent tube being connected in series with an attenuator and a ballast and a base load or an incandescent lamp load connected in parallel, and the electrode of the fluorescent tube being preheated with a heating transformer," characterized in that for controlling light -the fluorescent tube (7) is equipped with an ignition device (6) with an elevated ignition voltage which is connected on the input side to the outputs (S, ~ LI) of the damper (1) and on the output side to the electrodes (9) of the fluorescent tube (7), and which at each half-wave synchronously in relation to the rise of the phase partial voltage produced by the damper (1) delivers an ignition pulse. 2. Circuit according to claim 1, characterized in that the ignition device (6) contains a series circuit of a phase estimator (61), a switch-on delay (62), a noise pulse switch (63), a pulse amplifier (64), an ignition pulse generator (65), an ignition pulse transformer (66) and a capacitor (68), the input of the phase partial estimator (61) being connected to the controlled output (S) of the attenuator (1), and connected at its second input of the ignition pulse generator (65) to that of the attenuator (1) coupled phase (LI).